Quantum Entanglement Halves the Oblivious Update Bandwidth

Abstract

We consider (n,k) MDS-coded distributed storage over Fq with per-node storage α symbols. For the oblivious update problem, where a single message symbol changes and neither helpers nor the stale node know which, the classical lower bound is αk 2 q bits. We prove that when the k contacted helpers share prior quantum entanglement, the update bandwidth is α/2 · k 2 q bits-equivalent, a factor approaching 2 reduction. For α= 2, a [[k, k-2]]q CSS code achieves bandwidth k 2 q with one qudit per helper. For general α, a [[ α/2 k, α/2 k - α]]q CSS code achieves the bound with α/2 qudits per helper. The matching converse uses the superdense coding bound: the stale node holds all transmitted qudits and hence the entangled partners, so each helper's channel supports at most D2 distinguishable signals for dimension D. The result holds for all (n,k) pairs with sufficiently large prime q.